(Regressed) Holliday Junctions to Functio - American Chemical Society

Jul 7, 2011 - Holliday junction substrate reflective of a regressed replication fork. Our results demonstrate that, in reactions requiring ATP hydroly...
0 downloads 0 Views 4MB Size
Article pubs.acs.org/biochemistry

The Werner and Bloom Syndrome Proteins Help Resolve Replication Blockage by Converting (Regressed) Holliday Junctions to Functional Replication Forks Amrita Machwe,† Rajashree Karale,† Xioahua Xu,‡ Yilun Liu,‡ and David K. Orren*,† †

Graduate Center for Toxicology and Markey Cancer Center, University of Kentucky College of Medicine, Lexington, Kentucky 40536, United States ‡ Department of Therapeutic Radiology, Yale University School of Medicine, New Haven, Connecticut 06510, United States S Supporting Information *

ABSTRACT: Cells cope with blockage of replication fork progression in a manner that allows DNA synthesis to be completed and genomic instability minimized. Models for resolution of blocked replication involve fork regression to form Holliday junction structures. The human RecQ helicases WRN and BLM (deficient in Werner and Bloom syndromes, respectively) are critical for maintaining genomic stability and thought to function in accurate resolution of replication blockage. Consistent with this notion, WRN and BLM localize to sites of blocked replication after certain DNA-damaging treatments and exhibit enhanced activity on replication and recombination intermediates. Here we examine the actions of WRN and BLM on a special Holliday junction substrate reflective of a regressed replication fork. Our results demonstrate that, in reactions requiring ATP hydrolysis, both WRN and BLM convert this Holliday junction substrate primarily to a four-stranded replication fork structure, suggesting they target the Holliday junction to initiate branch migration. In agreement, the Holliday junction binding protein RuvA inhibits the WRNand BLM-mediated conversion reactions. Importantly, this conversion product is suitable for replication with its leading daughter strand readily extended by DNA polymerases. Furthermore, binding to and conversion of this Holliday junction are optimal at low MgCl2 concentrations, suggesting that WRN and BLM preferentially act on the square planar (open) conformation of Holliday junctions. Our findings suggest that, subsequent to fork regression events, WRN and/or BLM could re-establish functional replication forks to help overcome fork blockage. Such a function is highly consistent with phenotypes associated with WRN- and BLM-deficient cells.

R

specificities, preferring to act on complex DNA structures, including forks, bubbles, D-loops, triplexes, Holliday junctions, and G-quartets.7 Although not as well-characterized, RECQ4 has weak helicase activity that is stimulated by including complementary DNA strands in unwinding reactions.8 Surprisingly, WRN, BLM, RECQ4, and several other RecQ helicases facilitate the annealing of complementary DNA strands.9−12 Under certain circumstances, RecQ helicases (including WRN and BLM) can coordinate their unwinding and annealing activities to perform strand exchange.13,14 These biochemical studies suggest that at least a subset of human RecQ helicases may be structurally designed and enzymatically suited to act on three- and four-stranded DNA replication and recombination intermediates. In addition to unwinding and annealing activity, WRN is the only human RecQ homologue that also possesses a 3′ to 5′ exonuclease activity with similar substrate specificity for complex DNA structures as described above.15−17 A significant threat to genome stability is blockage of DNA synthesis that occurs when replication forks encounter DNA

ecQ helicases are critical for maintaining genomic stability, although their precise molecular functions are still unclear. There are five human RecQ family members (RECQ1, BLM, WRN, RECQ4, and RECQ5), and loss of function of BLM, WRN, and RECQ4 proteins is associated with Bloom (BS), Werner (WS), and Rothmund-Thomson (RTS) syndromes, respectively.1−3 A hallmark feature of all these syndromes is an increased incidence of cancer that is particularly prominent in BS. In addition to an elevated predisposition particularly to soft tissue sarcomas and osteosarcomas, WS is also characterized by early onset and an increased frequency of many other agerelated phenotypes.4,5 A high incidence of osteosarcoma and abnormalities in skeletal development and skin pigmentation are associated with RTS.2,6 At the cellular level, loss of BLM, WRN, or RECQ4 function results in an increased number of chromosomal aberrations that likely underlie the elevated cancer incidence of these syndromes. However, BS, WS, and RTS phenotypes differ significantly, suggesting these enzymes have some nonredundant functions. RecQ members share extensive homology within conserved sequence motifs characteristic of DNA-dependent ATPases and helicases, and most possess 3′ to 5′ nucleic acid unwinding activity. WRN and BLM have very similar DNA substrate © 2011 American Chemical Society

Received: January 21, 2011 Revised: June 6, 2011 Published: July 7, 2011 6774

dx.doi.org/10.1021/bi2001054 | Biochemistry 2011, 50, 6774−6788

Biochemistry

Article

(and BLM) exhibits enhanced binding to and action on this Holliday junction substrate at low Mg 2þ concentrations, suggesting they preferentially act on the square planar conformation of Holliday junctions. Our results suggest that WRN and/or BLM might act to reset the replication fork subsequent to fork stalling and regression, functions that are highly consistent with the replication abnormalities and specific genomic instability phenotype(s) associated with WS and BS.

damage, abnormal DNA structures, or proteins bound to parental DNA. To ensure survival subsequent to such encounters, cells have evolved pathways to deal with replication fork blockage that facilitate replication restart and completion of normal DNA synthesis. RecQ helicases, including WRN and BLM, are commonly postulated to act in pathways that overcome replication fork blockage.18−20 Consistent with this hypothesis, WRN-deficient cells are hypersensitive to replication blocking agents, including hydroxyurea (HU), topoisomerase inhibitors, and interstrand cross-linking agents such as mitomycin C, grow slowly in culture with an extended S-phase, and exhibit specific replication abnormalities, including asymmetry in normal bidirectional replication fork progression.21−24 Furthermore, in normal cells, with the use of DNAdamaging treatments with HU or other agents, WRN is recruited to sites of blocked replication and colocalizes with other replication factors in distinct nuclear foci.25−27 Similarly, BLM-deficient cells are also hypersensitive to mitomycin C, hydroxyurea, and aphidicolin and exhibit replication abnormalities, including problems in restart of replication forks after HU and aphidicolin treatment.28−32 Following DNA-damaging treatment with HU or the interstrand cross-linking agent psoralen, BLM also relocalizes to sites of ongoing replication that contain PCNA and other replication factors.33,34 Collectively, this evidence suggests that both WRN and BLM may be involved in pathways responding to replication blockage. According to some models, an initial step in dealing with a blocked replication fork may be fork regression to generate a Holliday junction or “chicken foot” intermediate.20,35−37 Following fork regression, the block to replication may be overcome by (1) repair of the DNA lesion and reverse branch migration to re-establish a fork structure, (2) use of an extended lagging daughter strand as a template for the synthesis of the leading strand followed by reverse branch migration to bypass the blocking lesion to re-establish the fork, or (3) use of the free double-stranded end of this Holliday junction to initiate RAD51-mediated strand invasion and re-establishment of a functional replication fork. Alternatively, processing or resolution of the Holliday junction could generate a doublestrand break that also could be utilized by RAD51-mediated recombinational pathways to restore a functional replication fork. In any case, a coordinated, error-free mechanism for resolution of replication blockage and re-establishment of the replication fork is absolutely critical for maintaining genome stability and promoting cell survival. As both WRN and BLM bind to and branch migrate Holliday junctions in vitro,25,38−40 each could potentially convert a regressed fork back to a functional replication fork. To determine if WRN and/or BLM might catalyze this important step in resolution of replication blockage, we constructed a specialized Holliday junction structure and investigated whether WRN or BLM could convert it to a four-stranded fork structure that could subsequently be subject to DNA replication. Our results demonstrate that both WRN and BLM efficiently catalyze conversion of this Holliday junction to a replication fork structure, with its leading daughter strand capable of being extended in vitro by DNA polymerases. Consistent with the idea that WRN and BLM target the Holliday junction structure to initiate branch migration, this conversion reaction was inhibited by RuvA and more efficient with WRN and BLM compared to the known branch migration enzyme RAD54. Also, WRN



EXPERIMENTAL PROCEDURES

Enzymes. All recombinant human WRN proteins (WRNwt, WRN-E84A, and WRN-K577M) used in these studies were overexpressed in insect cells and purified as previously described.41 WRN-E84A contains a glutamate to alanine mutation that abolishes its 3′ to 5′ exonuclease activity but preserves its normal DNA-dependent ATPase, helicase, and annealing activities; WRN-K577M contains a lysine to methionine mutation that abolishes ATPase and helicase activity but retains exonuclease activity.14,16,42 To generate mock preparations, insect cells infected with baculovirus without WRN sequences were lysed and subjected to purification procedures identical to those used for WRN proteins. Recombinant human RECQ4 was purified as described previously.8 Human wild-type BLM and BLM-D795A protein containing an aspartate to alanine mutation that abolishes its ATPase and helicase activities were gifts from J. Groden (The Ohio State University, Columbus, OH), while human RPA and human (four-subunit) DNA polymerase δ were gifts from G.-M. Li (University of Kentucky). Purified Escherichia coli UvrD and human RAD54 were obtained from S. Matson (University of North Carolina, Chapel Hill, NC) and A. Mazin (Drexel University, Philadelphia, PA), respectively. Purified E. coli RuvA was purchased from B-Bridge International. Klenow fragment (3′ to 5′ exo− ), from New England Biolabs, is an N-terminal truncation of E. coli DNA polymerase I that lacks both 5′ to 3′ and 3′ to 5′ exonuclease activities but retains polymerase activity. T4 DNA polymerase and T4 polynucleotide kinase were purchased from New England Biolabs. Proteinase K was obtained from Invitrogen. DNA Substrate Construction. The sequences of oligonucleotides (purchased from Integrated DNA Technologies) used in this study are listed in Table 1 of the Supporting Information. LeadD81, LagP70, and 3-way-base62 were radiolabeled (indicated by asterisk hereafter and in figures) at their 5′ ends by standard procedures using [γ-32 P]ATP and T4 polynucleotide kinase, and unincorporated nucleotide was removed using a spin column (Roche Applied Science). Unlabeled LagD84 was annealed to *LeadD81 by being heated to 95 °C for 5 min and slowly cooled; in parallel, unlabeled LeadP122 and LagP122 were similarly annealed. The resulting two-stranded fork structures were annealed to each other for 16 h at 25 °C to generate a singly labeled, static Holliday junction structure (see Figure 1A, left). To generate the fourstranded replication fork substrate, the heating and slow cooling procedure was used to anneal (1) *LeadD81 with unlabeled LeadP122 and (2) unlabeled LagD84 with unlabeled LagP122; subsequently, the resulting partial duplexes were annealed for 16 h at 25 °C. Two-stranded fork (*LeadD81/ LagD84 and *3-way-base62/3-way-5′flap), partial duplex (*LeadD81/LeadP122 and *LagP70/LagD30), and three-way junction (*3-way-base62/3-way-3′flap/3-way-5′flap) DNA substrates were generated by annealing the relevant oligonucleotides using the heating and slow cooling procedure. After formation, 6775

dx.doi.org/10.1021/bi2001054 | Biochemistry 2011, 50, 6774−6788

Biochemistry

Article

Figure 1. Diagram of Holliday junction substrate structure, conversion, and extension products. Schematic showing putative WRN- or BLMmediated conversion of our specialized Holliday junction structure (left) to a replication fork (center) with subsequent DNA polymerase-mediated extension from the 3′ end of the labeled (denoted with an asterisk) leading daughter strand of the fork. Most experiments utilized Klenow fragment, 3′ to 5′ exo− as DNA polymerase, resulting in strand displacement and new DNA synthesis (denoted with a dotted gray line) to the end of the parental leading strand template (right). While the vertical arms of this Holliday junction substrate are nonhomologous, the left arm is completely homologous to the proximal 51−54 bp of the right arm except for 5 bp of nonhomology (denoted with a solid gray segment) at the junction. This design ensured a static Holliday junction structure that could be converted to a replication fork structure (by enzymatically branch migrating the junction rightward, overcoming the short nonhomologous segment). Note that in the context of the Holliday junction, two nucleotides at the 3′ end of the labeled strand were unpaired; upon conversion to replication fork structure, these nucleotides are fully base-paired. Names of the oligos used for substrate construction are italicized; nucleotide sequences for these oligos are given in Table 1 of the Supporting Information.

PAGE (10%); after gel drying, exonucleolytic degradation from the 5′ end-labeled *LeadD81 strand of the substrate and/or products was visualized by phosphorimaging. Assays were also performed to study the action of DNA polymerases on the conversion product as well as various control substrates. For these studies, Holliday junction, four-stranded replication fork, and two-stranded fork (*LeadD81/LagD84) substrates (2−4 fmol) were incubated with or without either WRN-E84A, a mock preparation of WRN, BLM, or BLMD795A (at concentrations specified in the figure legends) in WRN reaction buffer (20 μL) containing 4 mM MgCl2 , either 1 mM ATP or 1 mM ATPγS, and 100 μM dNTPs. Following incubation at 37 °C, Klenow (3′ to 5′ exo− ) (0.01−0.001 unit/ reaction), T4 DNA polymerase (0.005 unit), or human DNA polymerase δ (60 fmol) was added with further incubation at 37 °C (times indicated in figure legends). These reactions were stopped by withdrawing a 10 μL aliquot from the reaction mixture and adding an equal volume of formamide loading buffer (95% formamide, 20 mM EDTA, 0.1% bromophenol blue, and 0.1% xylene cyanol). The DNA products were subsequently heated at 90 °C for 5 min and separated by denaturing PAGE (6%) in 1× TBE at 40−45 W for 1.5 h. The gels were dried and analyzed by phosphorimaging as described above. The percentage of extension (by Klenow) of the labeled leading daughter strand (of four-stranded forks converted from Holliday junctions) was calculated by dividing the combined signal for all products with higher molecular weights (compared to that of the original unextended strand) by the total radioactive signal from the entire lane (amount of unextended leading daughter strand + combined extended products). Electrophoretic Mobility Shift Assay (EMSA). Holliday junction substrate (∼4 fmol) was incubated with WRN-E84A (0−12 fmol) in WRN reaction buffer (20 μL) supplemented with either 1 or 8 mM MgCl2 for 10 min at 25 °C. Subsequently, 1 /6 volume of 30% glycerol was added and samples were separated by native PAGE (3.5%, acrylamide:bisacrylamide cross-linking ratio of 37.5:1) in 0.5× TBE at 100 V for 2 h. The gels were dried and subjected to phosphorimaging analysis as described above. WRN-E84A binding was assessed by comparing the amount of bound DNA with the total amount of DNA for each reaction [% DNA bound = (DNA bound/total DNA) × 100].

all substrates were purified by native polyacrylamide (6%) gel electrophoresis, excised from the gel after autoradiography, eluted for 24 h into buffer containing 10 mM Tris (pH 8.0) and 10 mM NaCl, and stored at 4 °C. Enzymatic Assays. For studying the conversion of the Holliday junction to fork DNA, Holliday junction substrate (∼2 fmol) was incubated for the specified times at 37 °C with WRN-E84A, WRN-wt, WRN-K577M, BLM, BLM-D795A, RAD54, RECQ4, or UvrD (at concentrations indicated in the figure legends) in WRN reaction buffer (20 μL) containing 40 mM Tris-HCl (pH 8.0), 0.1 mg/mL BSA, 5 mM dithiothreitol, and 0.1% Nonidet P-40 supplemented with MgCl2 (0.5−8 mM, as indicated) and either ATP (0.125−2 mM) or ATPγS (1 mM). Prior to incubation at 37 °C in specific experiments, (1) RuvA (4−1000 fmol) was preincubated with Holliday junction substrate for 5 min at 4 °C before addition of WRN-E84A or BLM, or (2) RPA (2.5−80 fmol) was added subsequent to WRN-E84A while the reaction mixtures were kept at 4 °C. Unwinding assays using twostranded fork and partial duplex substrates were performed similarly; however, assays with RECQ4 and three-way junction substrate also contained a 25-fold excess of unlabeled 3-waybase62 oligomer. Reactions were terminated by the addition of 5 mM EDTA; then, 10 μg of proteinase K was added, and the samples were incubated at 37 °C for 10 min. Following addition of 1 /6 volume of loading dye (30% glycerol, 0.25% bromophenol blue, and 0.25% xylene cyanol), samples were subjected to native polyacrylamide (5−6%) gel electrophoresis (PAGE) in 1× TBM [90 mM Tris-borate (pH 8.0) and 5 mM MgCl2 ] at 125 V for 3.5 h. The gels were dried, and the radioactivity associated with the DNA products was visualized and quantitated by phosphorimaging analysis (Storm 860 phosphorimager and ImageQuant, GE Healthcare). Conversion of Holliday junction to four-stranded replication fork was measured as a percentage of the radioactivity associated with replication fork to that of the total DNA, after subtraction of low background levels of DNA species present in control reaction mixtures without enzyme. Similarly, substrate unwinding was quantified as the percentage of radioactivity associated with the unwound product with respect to the total DNA in the reaction, again correcting for any background level of the product species in reactions without enzyme. To assess the 3′ to 5′ exonuclease activity inherent in WRN-wt and WRN-K577M, DNA products from reactions performed as described above were separated by denaturing 6776

dx.doi.org/10.1021/bi2001054 | Biochemistry 2011, 50, 6774−6788

Biochemistry



Article

shown previously that the mobility of Holliday junctions in polyacrylamide gels is influenced by divalent cation concentration,43,44 we included 5 mM MgCl2 (and omitted EDTA) in both our gels and running buffers. Under these conditions, we obtained adequate separation between the Holliday junction and the four-stranded fork DNA, the former migrating substantially slower than the latter. Theoretically, unwinding of a fourstranded Holliday junction by a helicase could yield a number of one-, two-, or three-stranded products; in fact, WRN and BLM have been previously shown to unwind partly mobile Holliday junction substrates to generate partial duplex as well as singlestranded products.39,40 However, when we incubated our specialized Holliday junction substrate with either WRN-E84A or BLM in the presence of 4 mM MgCl2 and 1 mM ATP, the primary product generated over time was the four-stranded replication fork structure (Figure 2A−D); little or no further unwinding of this fork to a partial duplex (*LeadD81/ LeadP122) was detected. In addition to the conversion of Holliday junction to four-stranded fork, some unwinding of the Holliday junction to form the two-stranded *LeadD81/LagD84 fork species was also observed in these reactions (Figure 2A,B). Conversion of Holliday junction to four-stranded fork by both WRN-E84A and BLM was direct; i.e., formation of the fourstranded fork did not result from separate unwinding and annealing steps. Note that the *LeadD81/LagD84 species could not be a relevant intermediate in fork formation and no significant amounts of other products were detected at early time points in kinetic assays (Figure 2A,B). Notably, this conversion reaction requires ATP hydrolysis, as fork formation was not detected in reaction mixtures lacking ATP or containing ATPγS, a nonhydrolyzable analogue of ATP (Figure 2E,F). Furthermore, use of ATPase- and helicase-deficient BLM-D795A or WRNK577M mutant proteins in these reactions also did not cause any detectable conversion of Holliday junction to fork product (Figure 2F and Figure 1 of the Supporting Information), confirming that these ATPase- and helicase-dependent conversion reactions are specifically catalyzed by BLM and WRN. Notably, the Holliday junction substrate is subjected to degradation by the 3′ to 5′ exonuclease activity retained in WRN-K577M (Figure 1 of the Supporting Information, bottom panel). The precise structure of Holliday junctions is known to be variable depending on Mg2þ ion concentration, with a stacked X-structure becoming favored over a square planar structure as the Mg2þ concentration increases. 43,44 Because our results and previous reports show that WRN and BLM readily act on Holliday junction structures, it is highly relevant to also determine the effect of MgCl 2 concentration on WRN- and BLM-mediated conversion of our Holliday junction to replication fork product, keeping in mind that Mg 2þ is a required cofactor in these reactions. In the presence of a fixed amount of ATP (1 mM), the amount of conversion of a Holliday junction to fork product by WRN-E84A was highly dependent on the MgCl 2 concentration (Figure 2G), being optimal between 0.5 (the minimal concentration tested) and 2 mM MgCl2 . The level of WRN-E84A-mediated conversion declined sharply at 4 mM MgCl 2 and even more drastically at 8 mM MgCl2 . To determine whether it is the absolute concentration of MgCl 2 or the MgCl 2 :ATP ratio in the reaction mixture that influences this activity, reactions were set up in which ATP concentration was varied over a wide range (0.125−2 mM) in the presence of 1 mM MgCl 2 , an optimal concentration in the experiment described above.

RESULTS

Specialized Holliday Junction Substrate Design. It has been postulated that, as part of a pathway to overcome replication blockage, some RecQ helicases, including WRN and BLM, may reset the replication fork from Holliday junctions (or chicken foot structures) generated by fork regression. 18,20 To examine a potential role for WRN or BLM in re-establishing a functional replication fork following regression, we constructed a special Holliday junction substrate (Figure 1, left) using a two-step process: independently annealed *LeadD81/ LagD84 and LeadP122/LagP122 species were subsequently annealed to one another. The resulting Holliday junction substrate contained two 30 bp arms (pictured vertically in Figure 1) that were completely nonhomologous; the left arm was completely homologous to the proximal 51−54 bp of the right arm, except for five nonhomologous base pairs at the junction. As constructed, this structure was static but could potentially be converted to a four-stranded replication fork (Figure 1, center) by branch migration of the Holliday junction (rightward in this orientation) through the region of nonhomology. In the event this conversion occurred, this replication fork structure would contain a three-nucleotide single-stranded gap on the leading arm at the fork junction. In the original Holliday junction substrate, the strand that would become the leading daughter strand following conversion to fork was labeled so that DNA polymerase-mediated extension from its 3′ end could be monitored. In the context of the Holliday junction structure, the last two nucleotides on the 3′ end of this strand were unpaired; this ensured that this strand could not be extended by a DNA polymerase unless conversion occurred (or without removal of the unpaired nucleotides by a 3′ to 5′ exonuclease). The design of this substrate allowed us to monitor enzyme-mediated conversion to the four-stranded replication fork structure by assaying (1) a structure-dependent change in migration by native PAGE and (2) extension from the 3′ end of the labeled strand by DNA polymerases, analyzed by denaturing PAGE. Notably, strand displacement activity inherent in Klenow fragment (and, to a lesser degree, in human DNA polymerase δ) allowed polymerization of the labeled leading daughter strand of the four-stranded fork structure (Figure 1, center) beyond the fork junction to the end of the leading parental strand template to generate labeled extension products of up to 122−123 nucleotides (Figure 1, right). The following sections detail how purified WRN and BLM proteins act on this specialized Holliday junction substrate. WRN and BLM Convert Holliday Junction Substrate to Four-Stranded Replication Fork. To test the hypothesis that RecQ helicases may be able to act on a Holliday junction structure reflecting a regressed fork and re-establish a functional replication fork, our Holliday junction substrate was incubated with or without purified enzymes. For most WRN-containing reaction mixtures, the exonuclease-deficient WRN-E84A mutant was used so that the reaction products could be analyzed without complication from possible digestion of the substrate or the products; importantly, use of this mutant also eliminated the possibility that the 3′ to 5′ exonuclease activity of WRN could remove the two unpaired nucleotides on the 3′ end of the labeled strand of the original Holliday junction substrate. Under standard conditions of electrophoresis using native PAGE with 1× TBE as the running buffer, the mobilities of the Holliday junction substrate and the four-stranded fork DNA marker representing the conversion product were quite similar. Because it has been 6777

dx.doi.org/10.1021/bi2001054 | Biochemistry 2011, 50, 6774−6788

Biochemistry

Article

Figure 2. ATP and Mg2þ dependence of the direct conversion of specialized Holliday junction to a replication fork by WRN-E84A and BLM. Holliday junction substrate (∼2 fmol) was incubated with (A) WRN-E84A (18 fmol) or (B) BLM (12.5 fmol) in MgCl 2 (4 mM) and ATP (1 mM) at 37 °C for the indicated times. DNA products (lanes 1−6) and marker substrates (lane 7, four-stranded replication fork, *LeadD81/LeadP122 partial duplex, *LeadD81/LagD84 fork, and *LeadD81 oligomer, migration positions depicted at the right) were analyzed by native PAGE as described in Experimental Procedures. Relative positions of migration of these marker substrates are applicable for panels B, E, and F and elsewhere. (C) Percentages of replication fork formation (calculated as described in Experimental Procedures) mediated by WRN-E84A plotted vs time for ATP-containing reactions conducted as described for panel A. Data are the mean and SE of three independent experiments. (D) Data from experiments performed as described for panel B were calculated and presented as described for panel C. (E) Holliday junction substrate (∼2 fmol) was incubated for 30 min at 37 °C with WRN-E84A (15 fmol) with or without ATP or ATPγS (1 mM) as indicated, and the DNA products were analyzed by native PAGE as described for panel A. Positions of migration of specific DNA structures are depicted here at right and also in panel F. (F) Holliday junction substrate (∼2 fmol) was incubated with BLM (12.5 fmol) or BLM-D795A (ATPase- and helicase-deficient mutant) (37.5 fmol) with ATP or ATPγS (1 mM) as indicated and incubated at 37 °C for 30 min, and then analyzed as described for panel A. (G) Holliday junction substrate (∼2 fmol) was incubated with WRN-E84A (18 fmol) in the presence of ATP (1 mM) and varying concentrations of MgCl 2 (0.5, 1, 2, 4, and 8 mM) for 30 min at 37 °C, and the reaction products were analyzed by native PAGE as described in the legend of Figure 1. For three independent experiments, the mean percentage (±standard deviation) of conversion of Holliday junction to fork structure is plotted vs MgCl 2 concentration. In the inset of panel G, similarly, reaction mixtures containing Holliday junction substrate (∼2 fmol), WRN-E84A (18 fmol), 1 mM MgCl2 , and varying concentrations of ATP (0.125, 0.25, 0.5, 1, and 2 mM) were incubated for 30 min at 37 °C and the percentage of conversion to fork structure is depicted for each MgCl2 :ATP ratio. (H) Holliday junction substrate (4 fmol) was incubated with WRN-E84A (0, 1.5, 3, 6, 9, and 12 fmol) in the absence of ATP and in the presence of either 1 or 8 mM MgCl 2 as indicated for 10 min at 25 °C, and protein−DNA complexes were resolved from free DNA by an EMSA as described in Experimental Procedures. The percentage of Holliday junction bound by WRN-E84A is calculated as described in Experimental Procedures and denoted above each lane. Positions of free Holliday junction substrate and Holliday junction−protein (HJ−WRN) complexes are noted at the left.

are consistent with an effect of a higher Mg 2þ concentration on the structure of the Holliday junction substrate that weakens the ability of WRN-E84A and BLM to catalyze the conversion reaction. To further explore whether the nature of Holliday junction structure influenced enzyme function, we used EMSA to determine if there was any difference in the binding affinity of WRN-E84A for the Holliday junction substrate at low (1 mM) and high (8 mM) MgCl 2 concentrations. It has been shown previously that some RecQ helicases, including WRN and BLM, exhibit high-affinity binding and enhanced catalytic activities on three- and four-stranded DNA structures, including Holliday junctions and forks as compared to single-stranded and duplex DNA. 7,39,45,46 When binding reactions were performed in the presence of 1 mM MgCl2 , WRN-E84A formed stable and specific complexes with Holliday junction substrate as observed after EMSA (Figure 2H). The amount of enzyme−DNA complex was dependent on WRN-E84A, with >50% of the substrate bound at the highest concentration. Although discrete and stable binding was observed between WRN-E84A

Thus, the MgCl2 :ATP ratio in these reaction mixtures varied between 0.5 and 8. The results of this experiment (Figure 2G, inset) reveal no substantial difference in the conversion of Holliday junction to fork DNA by WRN-E84A over the range of MgCl2 :ATP ratios tested, with conversion percentages ranging between 28 and 38%. Given that the inhibitory effect of increasing the MgCl2 concentration from 2 mM to either 4 or 8 mM on fork formation was much stronger, our results suggest that a larger absolute amount of Mg2þ was inhibitory with respect to the WRN-mediated conversion process. In contrast, unwinding of a 3′ overhang partial duplex by WRN-E84A was not significantly inhibited by MgCl 2 concentrations up to 4 mM (Figure 2 of the Supporting Information), suggesting that the marked inhibition of the Holliday junction conversion reaction at Mg 2þ concentrations of ≥4 mM was not due to general loss of WRN catalytic activity. The effect of MgCl2 concentration on BLM-mediated conversion followed the same general pattern as that of WRN-E84A, although the inhibitory effect at 4 and 8 mM MgCl 2 was much less pronounced compared to that on WRN-E84A (Figure 3A of the Supporting Information). These findings 6778

dx.doi.org/10.1021/bi2001054 | Biochemistry 2011, 50, 6774−6788

Biochemistry

Article

Figure 3. WRN and BLM preferentially convert the Holliday junction to replication fork. (A) Holliday junction substrate (∼2 fmol) was incubated with WRN-E84A, BLM, or RAD54 at the indicated concentrations for 30 min at 37 °C in 1 mM MgCl2 and 1 mM ATP. DNA products of these reactions (lanes 1−14) and markers (lane 15) were analyzed as described in the legend of Figure 2A. (B) Holliday junction (∼2 fmol) or three-way junction substrate (5 fmol, plus 125 fmol of unlabeled 3-way-base62 trap strand) was incubated with human RECQ4 at the indicated concentrations for 30 min at 37 °C in 4 mM MgCl2 and 1 mM ATP. DNA products and markers were analyzed as described for panel A. (C) At the indicated concentrations, UvrD was incubated with either 2 fmol of Holliday junction substrate (lanes 1−6) or 5 fmol of two-stranded fork (*3-way-base62/3way-5′flap) substrate (lanes 8−10) for 30 min at 37 °C. Specific preformed DNA structures were loaded as markers (lane 7) with their positions of migration depicted on the left and right sides. (D) Holliday junction (∼2 fmol) was incubated without or with WRN-wt (7.5, 15, 30, and 45 fmol) for 30 min at 37 °C in 1 mM MgCl2 and 1 mM ATP. DNA products of these reactions (lanes 1−5) were analyzed both by native PAGE (top) and by denaturing PAGE (bottom). Also loaded on native PAGE were markers for replication fork and *LeadD81/LagD84 fork species (lane 6) and for the *LeadD81/LeadP122 partial duplex species (lane 7).

the protein−DNA complexes is higher at 1 mM than at 8 mM MgCl 2 . Taken together, our results indicate that increasing Mg 2þ concentrations (>2 mM) inhibit the binding and conversion activity of WRN on our Holliday junction substrate. Furthermore, these findings suggest that these enzymes preferentially bind to and act on the square planar

and Holliday junction DNA when binding reaction mixtures contained 8 mM MgCl 2 , the level of binding was significantly reduced at each concentration of WRN-E84A, with